Topic and time based media affinity estimation

ABSTRACT

An affinity server estimates an affinity between two different time based media events (e.g., TV, radio, social media content stream), between a time based media event and a specific topic, or between two different topics, where the affinity score represents an intersection between the populations of social media users who have authored social media content items regarding the two different events and/or topics. The affinity score represents an estimation of the real world affinity between the real world population of people who have an interest in both time based media events, both topics, or in a time based media event and a topic. One possible threshold for including a social media user in a population may be based on a confidence score that indicates the confidence that one or more social media content items authored by the social media user are relevant to the topic or event in question.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. patent application Ser. No.14/067,589, filed Oct. 30, 2013, and entitled “TOPIC AND TIME BASEDMEDIA AFFINITY ESTIMATION,” which is a continuation of U.S. patentapplication Ser. No. 13/548,901, filed Jul. 13, 2012, and entitled“TOPIC AND TIME BASED MEDIA AFFINITY ESTIMATION,” which claims benefitof U.S. Provisional Application No. 61/507,520, filed Jul. 13, 2011, andentitled “BROADCAST MEDIA AUDIENCE AFFINITY ESTIMATION.” U.S.application Ser. No. 14/067,589, U.S. patent application Ser. No.13/548,901 and U.S. Provisional Application No. 61/507,520 areincorporated by reference herein, in their entirety, for all purposes.

FIELD

The present invention relates generally to correlating social mediacontent with time based media events and topics to estimate audienceaffinities.

BACKGROUND

Online social media services, such as social networking sites, searchengines, news aggregators, blogs, and the like provide a richenvironment for users to comment on events of interest and communicatewith other users. Social media content items authored by users of socialnetworking systems often include references to events that appear intime based media such as television (TV) shows, news reports, sportingevents, movies, concert performances, and the like. However, althoughthe content items can sometimes refer to the time based media, thecontent items themselves typically are isolated from the events and timebased media that those content items refer to; for example, the contentitems appear in online social networks provided over the Internet, whilethe events occur in other contexts and systems, such as TV programmingprovided on broadcast systems.

SUMMARY

An affinity server determines an affinity score between two differenttime based media events (e.g., TV, radio, social media content stream),between a time based media event and a specific topic, or between twodifferent topics, where the affinity score is based on an intersectionbetween the populations of social media users who have authored socialmedia content items regarding the two different events and/or topics.The affinity score represents an estimation of the real world affinitybetween the real world population of people who have an interest in bothtime based media events, both topics, or in a time based media event anda topic.

Determining the affinity score between one or more time based mediaevents and/or one or more topics allows advertisers to optimizeadvertising expenditures in broadcast media by enabling them to moreeffectively target advertising to audiences based on their affinity fortime based media events or topics. Estimations of affinity can also beused by TV networks or advertisers to determine in which TV shows orother broadcast media to place promotions for upcoming programming.Estimations of affinity can also be used by individual users to obtainrecommendations for broadcast media they should seek out, based on theirown expressed interests in time based media or topics.

To estimate affinity, two populations are created, one for each mediaevent or topic. Each population includes those social media users whohave authored social media content items determined to be relevant tothe topic or event in question. The threshold for including a socialmedia user in a population may be based on a confidence score that isdetermined that indicates the confidence that one or more social mediacontent items authored by the social media user are relevant to thetopic or event in question. In creating the population, it is assumedthat if a social media user has authored one or more social mediacontent item relevant to a event or topic, then that social media userhas an interest (or “affinity”) to that event or topic.

For example, a population may be created for a TV show, where thepopulation consists of those social media users who have authored atleast one social media content item that is determined to be relevant tothat TV show. In the case of a topic, a population for a topic consistsof those social media users who have authored at least one social mediacontent item that is determined to be relevant to that topic.

The affinity score between the first event or topic and the second eventor topic is based on an intersection, in terms of number of social mediausers, between the two populations, that is users who are members ofboth populations. Generally, the greater the intersection between thepopulations, the greater the affinity score between the twoevents/topics. The affinity score may be normalized based on the sizesof the populations being overlapped, based on the cardinality of theunion between the populations, or based on other factors. The affinityscore may be further combined with an externally obtained measure of thetotal real world audience for a first time based media event in order toestimate the real world affinity for a second event or topic in thepopulation at large.

The features and advantages described in this summary and the followingdetailed description are not all-inclusive. Many additional features andadvantages will be apparent to one of ordinary skill in the art in viewof the drawings, specification, and claims hereof.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 illustrates the computing environment of one embodiment of asystem for estimating the affinity between time based media events orbetween a time based media event and a topic.

FIG. 2 is a block diagram and flowchart of an alignment and affinityestimation process at a high level according to one embodiment.

FIG. 3 is a conceptual diagram illustrating the relationship betweentime based media events, TV programming guide data and annotated events,and the alignments created between events and SM content items.

FIG. 4 is a block diagram and flowchart illustrating one embodiment ofsocial media to event alignment.

FIG. 5 is a block diagram and flowchart illustrating one embodiment ofsocial media to topic alignment.

FIG. 6 illustrates one example screenshot of a user interface fordisplaying affinity scores between a TV show and multiple lifestyletopics of social media users, according to one embodiment.

FIG. 7 illustrates one example screenshot of a user interface fordisplaying affinity scores between a TV show and a number of other TVshows, according to one embodiment.

FIG. 8 illustrates one example screenshot of a user interface fordisplaying affinity scores between a TV show and a number of brandtopics, according to one embodiment.

The figures depict various embodiments of the present invention forpurposes of illustration only. One skilled in the art will readilyrecognize from the following discussion that alternative embodiments ofthe structures and methods illustrated herein may be employed withoutdeparting from the principles of the invention described herein.

DETAILED DESCRIPTION I. System Overview

FIG. 1 illustrates the computing environment of one embodiment of asystem for estimating the affinity between a first time based mediaevent or topic and a second time based media event or topic. Theenvironment 100 includes social media (“SM”) sources 110, time basedmedia sources 120, the affinity server 130, a network 140, clientdevices 150, advertisers 160.

The SM sources 110 include social networks, blogs, news media, forums,user groups, etc. Examples of SM sources 110 include social networkingsystems such as Facebook™ and Twitter™. These systems provide aplurality of social media users with the ability to communicate andinteract with other SM users of the system.

Using social networking systems, each SM user can author a wide varietyof types of SM content items including, for example, posts, videos,photos, links, status updates, blog entries, tweets, profiles, and thelike. These SM content items may refer to time based media events orother SM content items (e.g., other posts, etc., pages associated withTV shows or advertisements), other SM users. Through SM content items,SM users can engage in discussions, games, online events, and otherparticipatory services with other SM users. Each SM content item maycontain a timestamp indicating a time of creation. SM content items mayalso include information about the SM user, including biographicalinformation, geographical information, the topics the SM user isinterested, or other information. From the social media sources 110 itis possible to determine the author of any given SM content item.

Examples of such SM content items include content items containing audioclips of commentators on, or participants of, another event (e.g.,announcers on TV or radio) and text transcriptions thereof (generatedmanually or automatically), event-related information (e.g., recipes,instructions, scripts, etc.), statistical data (e.g., sports statisticsor financial data streams), news articles, and media usage statistics(e.g., user behavior such as viewing, rewind, pausing, etc.).

The time based media sources 120 include media broadcasters, directcontent providers, advertisers, and any other third-party providers oftime based media content. These sources 120 typically publish contentsuch as television shows (including network, cable, independent,affiliate sources), videos, movies, serials, radio broadcasts,commercials or advertisements in any of foregoing, and any number ofother types of audio and video recordings. Time based media sources 120also provide TV guide programming guide data (or EPG data) containingscheduling information for TV shows as well as metadata regarding the TVshows.

The network 140 may comprise any combination of local area and/or widearea networks, the Internet, or one or more intranets, using both wiredand wireless communication systems.

The client devices 150 comprise computing devices that can receive inputfrom a user and can transmit and receive data via the network 140. Forexample, a client device 150 may be a desktop computer, a laptopcomputer, a smart phone, a personal digital assistant (PDAs), set-topreceiver, automobile media interface, or any other device includingcomputing functionality, user input and output means, and datacommunication capabilities. A client device 150 is configured tocommunicate with the SM sources 110, time based media sources 120,advertisers 160, and the affinity server 130 via the network 140.

Advertisers 160 include companies, advertising agencies, or any otherthird-party organizations that create, distribute, or promoteadvertisements for SM users through social networks or directly withclient devices 150, for example using a web browser. Advertisementsinclude not only individual advertisements (e.g., video ads, banner ads,links or other creatives), but also brands, advertising campaigns, andflights, and targeted advertisements. Advertisements may be published inthe social networks alongside other content, posted in websites hostedby web servers (not shown), sent directly to client devices 150, orinserted into time based media sources 120. Advertisements may be storedon servers maintained by the advertisers 160, they may be sent to theaffinity server 130 and stored there, they may be sent to the SM sources110 and stored there, and/or they may be sent to external web serversand stored there. Advertisements may be sent to users by external adservers (not shown), by web servers, by the SM sources 110, by theadvertisers 160, or by the client devices 150. These systems may alsowork in conjunction to request, create, and send advertisements.

The affinity server 130 estimates the affinity between a first timebased media event or topic and a second time based media event or topic.The affinity server 130 is a computer system that includes a web server200 and associated API 202, as well as a number of components that aredescribed with respect to FIGS. 2-8.

The web server 200 links the server 130 to the network 140 and the othersystems described in FIG. 1. The web server 200 serves web pages, aswell as other web related content, such as Java, Flash, XML, and soforth. The web server 200 may include a mail server or other messagingfunctionality for receiving and routing messages between the server 130and the other systems described in FIG. 1.

The API 202, in conjunction with web server 200, allows one or moreexternal entities to access information from the server 130. The webserver 200 may also allow external entities to send information to theserver 130 calling the API 202. For example, an external entity sends anAPI request to the server 130 via the network 140 and the web server 200receives the API request. The web server 200 processes the request bycalling an API 202 associated with the API request to generate anappropriate response, which the web server 200 communicates to theexternal entity via the network 140. The API may be used by a SM source110 to communicate information and requests to the server 130.

The affinity server 130 may be implemented using a single computer, or anetwork of computers, including cloud-based computer implementations.The computers are preferably server class computers including one ormore high-performance CPUs, 1G or more of main memory, as well as 500 GBto 2 Tb of computer readable, persistent storage, and running anoperating system such as LINUX or variants thereof. The operations ofthe server 130 as described can be controlled through either hardware orthrough computer programs installed in computer storage and executed bythe processors of such servers to perform the functions describedherein. The server 130 includes other hardware elements necessary forthe operations described here, including network interfaces andprotocols, security systems, input devices for data entry, and outputdevices for display, printing, or other presentations of data; these andother conventional components are not shown so as to not obscure therelevant details.

As noted above, server 130 comprises a number of “engines” an“aggregator” and an “estimator” each of which refer to computationallogic for providing the specified functionality. An engine can beimplemented in hardware, firmware, and/or software. An engine,aggregator, or estimator may sometimes be equivalently referred to as a“module,” “system”, or a “server.” It will be understood that the namedcomponents represent one embodiment of the present invention, and otherembodiments may include other components. In addition, other embodimentsmay lack the components described herein and/or distribute the describedfunctionality among the components in a different manner. Additionally,the functionalities attributed to more than one component can beincorporated into a single component. Where the engines described hereinare implemented as software, the engine can be implemented as astandalone program, but can also be implemented through other means, forexample as part of a larger program, as a plurality of separateprograms, or as one or more statically or dynamically linked libraries.In any of these software implementations, the engines are stored on thecomputer readable persistent storage devices of the server 130, loadedinto memory, and executed by the one or more processors of the system'scomputers. The operations of the server 130 and its various componentswill be further described below with respect to the remaining figures.As will become apparent, the various data processing operationsdescribed herein are sufficiently complex and time consuming as torequire the operation of a computer system such as the server 130, andcannot be performed merely in the human mind by mental steps.

II. Affinity Score Generation Overview

FIG. 2 is a block diagram of the affinity server 130 and flowchart forthe generation of an affinity score, according to one embodiment. Theaffinity server 130 includes a data ingest 302, an event airingdetection 314 system, an annotated event store (or repository) 316, a TVprogramming guide store 304, a SM to event alignment 322 engine, a SMstore 306, a SM to event mapping store 324, a SM to topic alignment 352engine, a topic store 350, a SM to topic mapping store 354, a populationset aggregator 356, a population store 358, an affinity estimator 360,and an affinity score store 362.

Data ingest 302 accesses and stores a number of different items ofinformation for the affinity server 130. Data ingest 302 receives SMcontent items from social media sources 110. Data ingest 302 alsoreceives metadata related to SM content items including, for example,identification information for the SM user who authored each SM contentitem, SM profile information (including SM user contact information suchas a user name in a social network, mobile number, email address or thelike), social graph information, and the history of the content itemseach SM user has produced. This data is stored in SM store 306.

Data ingest 302 also receives TV electronic programming guide data (“EPGdata”) from an external source such as time based media sources 120. TheTV programming guide data may be in the form of a data feed, forexample. The TV programming guide data provides metadata information asto where (e.g., channel, geographic region) and when specific TV showsare aired, and also provides information about those shows (e.g. cast,characters, episode descriptions, etc.). Programming guide data isreceived from broadcast and cable networks, multiple system operators,or third party services. This data is stored in TV programming guidestore 304.

Data ingest 302 may also receive streams of time based media from thetime based media sources 120, including for example, streams of TV showsand radio broadcasts. The time based media is received from, forexample, network broadcast, cable or satellite providers. The time basedmedia may include metadata that is transmitted along with the streams.The streams and any associated metadata may be processed to generateannotated events 316 that may be used in addition to or in place of theTV programming guide data.

Data ingest 302 may also receive topics from external third parties.Additionally, the affinity server 130 may also create topics on its own.Topics are stored in topic store 350. Topics are described below withrespect to FIG. 5.

The affinity server 130 uses the ingested data to estimate an affinityscore between two different time based media events (e.g., TV, radio,internet content stream), between a time based media event and aspecific topic, or between two different topics. To do this, the SM toevent alignment 322 engine aligns (or “maps”) the SM content items andtheir authors (i.e., SM users) with the TV programming guide data and/orannotated events 316. The alignments indicate which SM content items arerelevant to which events. Since each SM content item has an SM user asan author, it follows that the mappings also indicate which SM users arerelevant to which events. These mappings are stored in mapping store324. SM to event alignment 322 is described below with respect to FIG.4.

Separately, the SM to topic alignment 352 engine maps the SM contentitems and their authors with the topics. The mappings indicate which SMcontent items (and their authors) are relevant to which topics. Thesemappings are stored in SM to topic mapping store 354. SM to topicalignment 352 is described below with respect to FIG. 5.

To generate an affinity score, the affinity server 130 receives, atleast, a first time based media event or topic and second time basedmedia event or topic for which an affinity score is to be determined.The selected events and/or topics may be received externally, forexample from a user (e.g., an advertiser 160) providing input through aweb user interface, such as the one displayed in FIGS. 6-8 describedbelow.

A population set aggregator 356 selects SM users from the SM to topicmapping store 354 and SM to event mapping store 324 to create twopopulations. A first population includes those SM users who are alignedwith the first time based media event or topic. Thus, the firstpopulation represents those SM users who are determined to have aninterest in the first time based media or topic based on theirauthorship of SM content relevant to that time based media event ortopic. A second population includes those SM users who are aligned withthe second time based media event or topic. These populations are storedin the population store 358. Each population may be filtered using oneor more filtering criteria. The population set aggregator 356 isdescribed below.

An affinity estimator 350 determines an affinity score based on theintersection between the first and second populations. The affinityscore may be normalized by a number of different factors including, forexample, the sizes of each of the two populations and/or therelationship between the intersection and the other populations in therepository. The affinity score is stored in store 362. The affinityestimator 360 is described below.

III. Relationship between EPG Data, Annotated Events, and SM ContentItems

FIG. 3 is a conceptual diagram illustrating the relationship betweentime based media events, TV programming guide data and annotated events,and the alignments 322 created between events and SM content items. Asshown, time based media 451 includes multiple segments (segs. 1-M) 453,which contain events in the time based media. Both TV programming guidedata 359 and annotated events 359 each include a reference to one of theevents and one or more metadata instances 457 (1-N).

Metadata instances 457 can include, but are not limited to: the type ofevent occurring (e.g., TV show, advertisement), if the event is anadvertisement, the brand or product being advertised, the agentsactors/characters involved in the event, the scene/location of theevent, the time of occurrence and time length of the event, theresults/causes of the event, etc. For example, metadata for anadvertisement type event may include information such as “Brand:Walmart; Scene: father dresses up as clown; Mood: comic.” As illustratedin these examples, the metadata can be structured as tuples of <name,value> pairs.

Metadata instances 457 may also include low level features for an event,e.g., image or audio features or content features, hand annotations withtext descriptions, or both. Metadata may be represented as textdescriptions of time based media events and as feature vectorrepresentations of audio and/or video content extracted from examples ofevents. Examples of such metadata include a number and length of eachshot, histograms of each shot (e.g., color, texture, edges, gradients,brightness, etc.), and spectral information (e.g., frequencycoefficients, energy levels) of the associated audio. Metadata may begenerated using human annotation (e.g., via human annotators watchingevents or samples thereof) and may be supplemented with automaticannotations. Metadata may also include different types of featuresincluding but not limited to scale-variant feature transform (SIFT),speeded up robust features (SURF), local energy based shape histogram(LESH), color histogram, and gradient location orientation histogram(GLOH).

Annotated events 459 are aligned to one or more SM content items 461(A-O), using alignment process 322 as further described in conjunctionwith FIG. 4 below. Note that alignment processes 322, alignments may beone-to-one, many-to-one, and/or many-to-many. Thus, a given SM contentitem 461 can be mapped to multiple different annotated events 459 (e.g.,SM content items C, D, and F), and an annotated event 459 can be mappedto multiple different SM content items 461.

IV. Social Media to Event Alignment

FIG. 4 is a block diagram and flowchart illustrating one embodiment ofSM to event alignment 322. The alignments indicate which SM contentitems are relevant to which events. The annotated events are drawn fromthe TV programming guide data 304 as well as from annotated event store316.

IV.A. Filtering

In one embodiment SM filtering 502 is performed prior to SM to eventalignment 322. SM content items are filtered 502 in order to create aset of candidate content items with a high likelihood that they arerelevant to a specific event. For example, content items can be relevantto an event if they include a reference to the event. To performfiltering 502, a candidate set of content items is compiled based on thelikelihood that those content items are relevant to the events, forexample, by including at least one reference to a specific event. Acomparative feature extraction engine 510 is one mechanism for doingthis, and is described with respect to SM to event alignment 322.

At the simplest, this candidate set of content items can be the resultof filtering 502 associated with a given time frame of the event inquestion. Temporal filters often are, however, far too general, as manycontent items will only coincidentally co-occur in time with a givenevent. In addition, for broadcast TV, e.g., the increasing use ofdigital video recorders has broadened significantly the relevanttimeframe for events.

Additional filters 502 are applied based on terms used in the contentitem's text content (e.g., actual texts or extracted text from closedcaption or audio) that appear in the metadata for an event. Additionalfilters may also include domain specific terms from domain ontologies504. For example, content item of a social network posting of “TouchdownBrady! Go Patriots” has a high probability that it refers to an event ina Patriots football game due to the use of the player name, team name,and play name, and this content item would be relevant to the event. Inanother example, a content item of a post “I love that Walmartcommercial” has a high probability that it refers to an advertisementevent for Walmart due to the use of the store name, and the term“commercial,” and thus would likewise be relevant to this event.

A SM content item can be relevant to an event without necessarilyincluding a direct textual reference to the event. Various informationretrieval and scoring methods can be applied to the content items todetermine relevancy, based on set-theoretic (e.g., Boolean search),algebraic (e.g., vector space models, neural networks, latent semanticanalysis), or probabilistic models (e.g., binary independence, orlanguage models), and the like.

SM content items that do not pass certain of these initial filters,e.g., temporal or content filters, are removed from further processing,reducing the number of mappings that occur in the latter steps. Theoutput of SM filtering 502 is an updated SM content store 306, whichindicates, for each content item, whether that content item was filteredby temporal or content filters. Additional filters may apply inadditional domains.

IV.B. Social Media to Event Alignment

SM to annotated event alignment 322 includes a comparative featureextraction 510 and an alignment function 512. The comparative featureextraction 510 converts input of an annotated event 508 (and/or eventsstored in the TV programming guide data 304) and a SM content item 506into a feature vector representation, which is then input to thealignment function 512. The alignment function uses the receivedfeatures to create a relationship between the event features and SMfeatures. The relationship may be co-occurrence, correlation, or otherrelationships as described herein. The comparative feature extraction510 also may receive input from the SM author store 308 and the domainontologies 504. The three major types of features extracted are contentfeatures 510 c, geo-temporal features 510 b, and authority features 510a.

Content features 510 c refer to co-occurring information within thecontent of the SM content items and the metadata for the video events,e.g., terms that exist both in the content item and in the metadata forthe video event. Domain ontologies 504 may be used to expand the set ofterms used when generating content features. In addition to exactmatches, the domain ontologies 504 that encode information relevant theTV show and/or advertising domain may be used to expand the term set toinclude synonyms and hypernyms (e.g., “hilarious” for “comic”), names ofcompanies, products, stores, etc., as well as TV show associated words(e.g., “episode”) and advertisement associated words (e.g.,“commercial”).

Geo-temporal features 510 b refer to the difference in location (e.g.,geographic region of airing) and time at which the input media wasgenerated from a location associated with the SM content item about theevent. Such information is useful as the relevance of SM to an event isoften inversely correlated with the distance from the event (in time andspace) that the media was produced. In other words, SM relevant to anevent is often produced during or soon after that event, and sometimesby people at or near the event (e.g., a sporting event) or exposed to it(e.g., within broadcast area for TV-based event).

For video events, geo-temporal information can be determined based onthe location and/or time zone of the event or broadcast of the event,the time it started, the offset in the video that the start of the eventis determined, the channel on which it was broadcast. For SM,geo-temporal information can be part of the content of the media itself(e.g., a time stamp on a blog entry or status update) or as metadata ofthe media or its author.

The temporal features describe the difference in time between when theSM content item was created from the time that the event itself tookplace. In general, smaller differences in time of production areindicative of more confident alignments. Such differences can be passedthrough a sigmoid function such that as the difference in timeincreases, the probability of alignment decreases, but plateaus at acertain point. The parameters of this function may be tuned based on anannotated verification data set. The spatial features describe thedistance from the author of the content item location relative to thegeographical area of the event or broadcast. Spatial differences areless indicative because often times people comment on events that takeplace far from their location. A sigmoid function may be used to modelthis relationship as well, although parameters are tuned based ondifferent held out data.

Authority features 510 a describe information related to the author ofthe SM and help to increase the confidence that a SM content item refersto a video event. The probability that any ambiguous post refers to aparticular event is dependent upon the prior probability that the authorwould post about a similar type of event (e.g., a basketball game for anauthor who has posted content about prior basketball games). The priorprobability can be approximated based on a number of features including:the author's self-generated user profile (e.g., mentions of a brand,team, etc.), the author's previous content items (e.g., about similar orrelated events), and the author's friends (e.g., their contentcontributions, profiles, etc.). These prior probability features may beused as features for the mapping function.

The alignment function 512 takes the set of extracted features 510 a-cand outputs a mapping 514 and a confidence score 516 representing theconfidence that the SM content item refers (or references) to the videoevent. For each feature type 510 a-c, a feature specific sub-functiongenerates a score indicating whether the SM content item refers to theannotated event. Each sub-function's score is based only on theinformation extracted in that particular feature set. The scores foreach sub-function may then be combined using a weighted sum, in order tooutput a mapping 514 and an associated confidence score 516, as shownbelow for an event x and a SM content item y:

align(feat(x, y))=[α·content(feat(x, y))]+[β·geoTemp(feat(x,y))]+[γ·author(feat(x, y))]

where α, β, and γ are the respective weights applied to the threefeature types, and align(feat(x,y)) is the confidence score. Both theweights in the weighted sum, as well as the sub-functions themselves maybe trained using supervised learning methods, or optimized by hand.

The output of the SM to event alignment 332 is a mapping between anannotated event and a SM content item. The mapping includes theconfidence score that has been determined between the annotated eventand the SM content item. In one embodiment, the SM content item isconsidered relevant to the annotated event if the confidence scoreexceeds a threshold. This mapping, along with the real-value confidencescore is stored in the mapping store 324.

IV.C. Social Media to Event Alignment Example

For example, a SM content item may say “I loved this GLEE episode. Canyou believe what Quinn just did.” The metadata for the TV show “GLEE”may include: {“Show: GLEE; Cast: Dianne Agron, Chris Colfer, etc.;Characters: Quinn, Kurt, etc.; Description: In this episode . . . ”}. Inthis example, the SM content item and the event metadata haveco-occurring (e.g., matching) content terms (e,g, “GLEE” and “Quinn”).In another example, the SM content item “I loved that hilarious Walmartclown commercial” and the metadata for an advertisement for Walmart{“Brand: Walmart, Scene: father dresses up as clown, Mood: comic”} haveco-occurring content terms (e.g., “Walmart” and “clown”). The matchesmay be considered generally, so that content appearing anywhere in a SMmessage can be matched against any terms or elements of the TV show oradvertisement metadata, or may be restricted to certain sub-partsthereof.

IV.D. Social Media User Alignment

The mappings 324 between SM content items and events may be translatedinto alignments between SM users and events. This alignment represents aconclusion that the SM user has an interest in the event based on theirauthoring of a SM content item that has been determined to be relevantto the event. The alignments between SM users and events may varydepending upon the implementation.

In one embodiment, if at least one SM content item has been determinedto be relevant to an event based on the confidence score, then the SMuser is aligned with the event. In other embodiments, the SM user isaligned with the event when the SM user has authored a threshold numberof SM content items determined to be relevant to the event.

In another embodiment, a total confidence score may be determined thatrepresents the confidence that an event is relevant (i.e., of interest)to a SM user. The total confidence score may be determined using aweighting function that takes into account the confidence scores, withrespect to the event, of some or all of the SM content items authored bythe SM user. For example, the function may sum these individualconfidence scores. If the total confidence score exceeds a threshold,the SM user is aligned with the event.

V. Social Media to Topic Alignment

FIG. 5 is a block diagram and flowchart illustrating one embodiment ofSM to topic alignment 352. The SM to topic alignment process 352 issimilar to the SM to event alignment process 322 described in FIG. 4.Thus, the description of the SM to topic alignment process 352 does notrepeat all of the details of this process. SM to topic alignment 352determines which SM content items, and also SM users, are relevant to atopic.

A topic is any concept, abstract or physically existing in the realworld, that can be described by words. Categories of topics include bothexpressly acknowledged interests of social media users (e.g., sports,movies, particular brands, musicians, current events, politics, etc.),as well as observed lifestyle patterns and demographics of SM users(e.g., video game players, users within a particular age range, coffeedrinkers, museum goers). Topics can be created around individual people(e.g., actors or musicians), groups of people (e.g., bands or sportsteams), products and brands (e.g., iPhone or Cadillacs), works of art(e.g., movies, books or songs), lifestyle segments (e.g. parents,technology enthusiasts), or any other concept that can be referred to insocial media.

Topics may be general in nature (e.g., the “candy” topic) or morespecific (e.g., “HERSHEY'S” brand chocolate vs. “CADBURY” brandchocolate). For example, HERSHEY'S may want to launch an advertisingcampaign to target users who have an affinity for their brand, and thus,a “brand topic” could be created to identify authors publishing socialmedia content item related to the HERSHEY'S brand. Similarly, a brandtopic could be created for a competitor brand (e.g., CADBURY) in orderto enable identification of SM users with an affinity for HERSHEY'S'scompetitors.

Topics are stored in topic store 350. Topics may be created by theaffinity server 130. Topics may also be provided by the advertiser 160.In one implementation, each topic is associated with one or morekeywords. These keywords may include Boolean expressions for determiningwhether some other item of information, for example a SM content item,matches the topic. Topics may also be associated with domain ontologiesthat expand the set of keywords to be matched against a topic based onsemantic similarity. Additionally, statistical machine learning can beused to train classifiers to be associated with various topics. Theseclassifiers may be used to predict the confidence that another item, forexample, a SM content item, matches the topic.

The affinity server 130 performs the SM to topic alignment process 352using the keywords and/or classifiers associated with a topic.Comparative feature extraction 510 is performed on a SM content item.The extracted features are matched (or aligned) 512 with the classifiersor keywords associated with a topic to identify if the SM content itemis relevant to a topic. As a result of the matching 512, a confidencescore 516 is determined regarding the alignment between the one or morekeywords or classifiers and the SM content item. The confidence score516 represents the confidence that the SM content is relevant to thetopic based on the extent of the matching between the keywords and/orclassifiers and the extracted features of the SM content item. If theconfidence score is sufficiently high, a mapping 514 is created betweenthe topic and the SM content item. This mapping 514, along with thereal-value confidence score 516 is stored in the mapping store 354.

The mappings 354 between SM content items and events may be translatedinto alignments between SM users and topics. The manner in which it isdetermined whether the SM user is aligned with a topic may varydepending upon the implementation. In one embodiment, if at least one SMcontent item has been determined to be relevant to a topic, then the SMuser is aligned with the topic. This alignment represents a conclusionthat the SM user has an interest in the topic based on their authoringof a SM content item that has been determined to be relevant to thetopic.

In another embodiment, a total confidence score may be determined thatrepresents the confidence that a topic is relevant (i.e., of interest)to a SM user. The total confidence score may be determined using afunction that takes into account the confidence scores, with respect tothe topic, of some or all of the SM content items authored by the SMuser. For example, the function may sum these individual confidencescores. If the total confidence score exceeds a threshold, the SM useris aligned with the topic.

For example, if an advertiser 160 wants to determine whether a user is apet owner (as one example of a lifestyle topic), the affinity server 130determines whether the user is a pet owner by using keywords/phrasesthat when used by an author, are indicative of being a pet owner. Thesekeywords/phrases might include, for example, “my dog”, “my cat”, “mykitten”, “our dog”, “our puppy”, and so on. The SM content itemsauthored by a given SM user may contain an example SM content itemstating “My dog slobbered all over the couch!”. Comparative featureextraction 510 extracts several features from this content item,including at least one (e.g., “my dog”) that matches the keywordsassociated with the pet owner topic. Consequently, alignment 512 maydetermine that there is a high level of confidence (e.g., a highconfidence score) that the SM content item is associated with the topicof being a pet owner. Based on this and other SM content items authoredby the SM user, the SM user is aligned with the pet owner topic.

VI. Time Based Media Audience Affinity Estimation

With reference to FIG. 2, the affinity server 130 is configured todetermine an affinity score representing the intersection between socialmedia users who have expressed interest in a first topic or time basedmedia event and social media users who have expressed interest in asecond topic or time based media event. As described above, the affinityserver 130 includes a population set aggregator 356, a population store358, an affinity estimator 360, and an affinity score store 362.

The affinity server 130 is configured to generate an affinity scorebetween a first topic or event and a second topic event. The eventsand/or topics may be received externally, for example from a user (e.g.,an advertiser 160) providing input through a web user interface, such asthe one displayed in FIGS. 6-8 described below. The population setaggregator 356 is configured to aggregate a first population for thefirst topic or event, and to aggregate a second population for thesecond topic or event. The affinity estimator 360 determines theaffinity score using at least the first and second populations.

VI.A. Population Aggregation and Filtering

The population set aggregator 356 aggregates a population of SM userswho are aligned with a topic or time based media event. The populationset aggregator 356 draws from the SM to topic mapping store 354 and theSM to event mapping store 324.

The population set aggregator 356 is configured to form a populationbased on a list of SM users who are aligned with a topic or event. TheSM users in a population may be identified both directly (e.g., by a SMuser profile name) or parametrically (e.g., by attributes listed in a SMuser profile), or by a combination thereof. In one implementation, if anSM user is aligned with the event or topic, they are included in thepopulation.

The population set aggregator 356 is also configured to aggregatepopulations based on metadata associated with events. For example, usersaligned to multiple TV shows can be aggregated into a single populationbased on the networks on which the shows air, the time of day the showairs, the genre of the show, the actors in the show, etc. Suchaggregations allow for affinity scores to be calculated between, forexample, brands or products, TV network names, lifestyle topics, genres,particular TV shows and TV dayparts, etc.

The population set aggregator 356 is also configured to filter apopulation according to one or more criteria in order to refine the listof SM users who make up the population. Population filtering allows forthe determination of an affinity score with respect to a more specificcriteria. This improves the ability of the affinity server 130 toprovide more specific information to advertisers, who may in turn usesthis information to specifically target their advertising efforts.

Criteria for filtering include, for example, filtering social mediausers based on social media user demographic information, the content ofauthored SM content items, or time of authorship of SM content items.The population set aggregator 356 is configured to combine multipledifferent filtering criteria when filtering a population. For example,in order to optimize an advertising campaign, an advertiser may chooseto filter a population to include only those SM users that areclassified as female in the age ranges of 30-45.

Demographic filtering criteria may include filtering the population toinclude only those SM users who match an age, gender, socioeconomicdata, or geographical location criteria. Demographic filtering criteriamay also be based on affiliations of users with groups formed withsocial media or social networking systems. For example, SM user'smembership in a fan club for a band or TV show may be used as afiltering criteria.

A content filtering criteria may specify that only those SM users whohave authored SM content items that mention one or more specifickeywords or their variants are included in a population. A contentfiltering criteria may also specify that only those SM users who haveauthored SM content items expressing a particular sentiment are includedin a population. For example, such a criteria may specify that onlythose SM users who have referred to a topic or event in a positivesentiment (e.g., expressed opinions that were favorable to the brand)are included in a population.

A time filtering criteria may specify that only those SM users who haveauthored SM content items regarding the topic or event in a particulartime range are included in the population. Such a criteria may, forexample, specify that only those SM users who have authored SM contentitems during the airing of a TV show (or within a specified time periodbefore or after) be included in a population. As another example, thecriteria may be more broadly defined to include those users who haveauthored SM content items at any point during an entire season of agiven TV show. In this manner, changes in affinity scores may be trackedbetween episodes or over the course of seasons.

VI.B. Affinity Estimation

The affinity estimator 360 uses the first and second populationsaggregated by the population set aggregator 356 to determine an affinityscore between the first topic or event and the second topic or event. Todo this, the affinity estimator 360 determines the intersection of SMusers between the first population and the second population. Thepopulation of intersecting SM users who are in both the first and secondpopulations may be stored as an intersecting population in thepopulation store 358.

The affinity score is a numerical value. The affinity score is afunction of the number of SM users in the intersecting population. Thegreater the intersection, the higher the affinity score. The affinityscore is stored in an affinity score store 362.

In one implementation, the affinity score is simply a count of thenumber of SM users in the intersecting population, i.e., in both thefirst population (population A) and the second population (populationB). In this case, the affinity score may be calculated as:

$\sum\limits_{a \in {Au}}\left( {A_{a}^{\prime} \times B_{a}^{\prime}} \right)$

In this equation, Au represents the set of all SM users, A′_(a)represents an indicator function that equals 1 if user a commented onevent/topic A, and B′_(a) represents an indicator function that equals 1if user a commented on event/topic B. In another implementation, thecount may be weighted by how many times each individual SM user in theintersecting population authors a SM content item on either one or bothof the first and second topics or events. Such a count weights theaffinity score based on how many times SM users have authored SM contentitems about a topic or event. In this case, the affinity score may becalculated as:

$\sum\limits_{a \in {Au}}\left( {A_{a} \times B_{a}} \right)$

In this equation, A_(a) represents the number of SM content items byuser a about event/topic A, and B_(a) represents the number of SMcontent items by user a about event/topic B.

In another implementation, the count may be weighted based on each SMuser's overall probability of authoring a SM content item on the firstand second topic or event. This probability is based on the other SMcontent items they have authored. In this case, the affinity score canbe calculated as:

$\sum\limits_{a \in {Au}}\left( {\frac{A_{a}}{C_{a}} \times \frac{B_{a}}{C_{a}}} \right)$

In this equation, C_(a) represents the total number of SM content itemsmade by user a. Such a count adjusts the weight of each SM user based onhow many SM content items they have authored (i.e., how “talkative” theyare in the context of the social networking system). In oneimplementation, more talkative users are weighted less heavily than lesstalkative users.

In another implementation, the count of the number of users in theintersecting population (or “overlap count”) is normalized by the totalnumber of SM users in the first or second population. This normalizationproduces an affinity score that represents the proportion of eachpopulation who are present in the other population. For example, theaffinity score may represent the proportion of SM users in the firstpopulation present in the second population, or the proportion of SMusers in the second population present in the first population. Inanother implementation, the overlap count is normalized by the number ofSM users who have commented on TV shows generally, or by the number ofSM users in the social networking system, or by some other aggregatemeasure of SM user behavior in the social networking system.

Depending upon how the affinity score is normalized, affinity scores notbe symmetrical, that is the affinity score of population A with respectto population B can be different from the affinity score for populationB with respect to population A. For example, an affinity score may bedetermined that represents the affinity that viewers of AMERICAN IDOL(first population) have for GLEE. This affinity score may be normalizedbased on the size of the population of SM users who have authored SMcontent items regarding AMERICAN IDOL. Another different affinity scoremay be determined that represents the affinity that viewers of GLEE(second population) have for AMERICAN IDOL. In contrast, this affinityscore may be normalized based on the size of the population of SM userswho have authored SM content items regarding GLEE. These two affinityscores may be different, and thus are not necessarily symmetric.

In another implementation, the affinity score can be calculated bydetermining the average probability of a SM user to author SM contentitems on event/topic A and event/topic B, normalized by the expectedprobability of any SM user to author SM content items on A and B. Thisis equivalent to normalizing the weighted overlap count, describedabove, and then further normalizing that by the product of theprobability of any given SM content item by any SM user being abouttopic/event A and the probability of any given SM content item by any SMuser being about topic/event B. These probabilities may be determined byanalyzing the contents of all available SM content items, bothgenerally, and about events/topics A and B specifically. Under such aformulation, the affinity score can be calculated as:

$\frac{\frac{1}{{Au}}{\sum\limits_{a \in {Au}}\left( {\frac{A_{a}}{C_{a}} \times \frac{B_{a}}{C_{a}}} \right)}}{\frac{A}{C} \times \frac{B}{C}}$

Where Au represents the set of all SM users, |Au| represents thecardinality of the set Au, A represents the total number of commentsabout event/topic A and B represents the total number of comments aboutevent/topic B and C represents the total number of comments made by anySM user.

Other normalization processes may be used, such as normalizing by thecardinality of the union of the first and second population, as well asnormalizing by the product of the cardinalities of the first and secondpopulations.

As described above, the affinity score is a determination that relies onthe expressed (or measured or observed) interests of SM users asprovided by their authored SM content items. Affinity scores may also beused to reveal the inferred (or unmeasured, or hidden) interests of SMusers that were not expressly made known. In one implementation,individual affinity scores between pairs of events and/or topics can becombined to reveal “inferred” affinity scores between other pairs ofevents and/or topics.

In one such implementation, affinity scores are inferred usingtechniques that exploit the correlation amongst the affinity scoresbetween events and/or topics. Many techniques exist for exploiting suchcorrelations. For example, matrix factorization methods, such asSingular Value Decomposition (SVD), can be applied to a matrix ofaffinity scores. Each row in the matrix represents a different event ortopic. The columns list the same events and/or topics as the rows, againwith each column representing a different event or topic. Using SVD,this matrix can be decomposed, its eigenvalues thresholded, and thenrecomposed to form a smoothed matrix in which each cell in the matrixrepresents the inferred affinity score between the correspondingevents/topics. In another implementation, similar results can beachieved using Hierarchical Bayes Models such as Latent DirichletAllocation, etc.

For example, using any of the techniques above, explicit affinity scoresmay be determined between several events and/or topics. Specifically, afirst affinity score may be determined between a first population and athird population, a second affinity score may be determined between asecond population and a fourth population, and a third affinity scoremay be determined between the third and fourth populations. Using SVD,Hierarchical Bayes Models, or another similar technique, the inferredaffinity score between the first and second populations may be inferredbased on the first, second, and third affinity scores previouslycalculated.

VI.C. Affinity Score Calculation Example

For example, assume a company that advertises on TV, for exampleHERSHEY'S chocolate company, wants to make better use of theiradvertising expenditures so that their advertisements air during TVshows whose audiences have affinity for candy. The affinity server 130may provide HERSHEY's with one or more affinity scores between topics ofinterest to HERSHEY's and TV shows that have aired.

To determine the affinity score between a TV show and a topic, theaffinity server 130 ingests one or more streams of SM content items, andone or more streams of the TV show. The affinity server 130 alsoreceives from HERSHEY's information identifying a particular topic ofinterest regarding the affinity that they want to target (e.g., thetopic of candy). The affinity server 130 may also receive or createkeywords associated with that topic (e.g., “chocolate bar”, “chewinggum”, “dark chocolate”). The affinity server 130 also receives TVprogramming guide data.

Event airing detection 314 is performed on the received TV show tocreate annotated events. The SM content items are aligned using theannotated events and information from the TV programming guide data asinputs to SM to event alignment 322. The SM content items are alsoaligned with the “candy” topic provided by HERSHEY's using the providedkeywords. A population set aggregator 356 creates two populations of SMusers, a first population of SM users who have been determined to havean affinity for the TV show, and a second population of SM users whohave been determined to have an affinity for the “candy” topic. Anaffinity estimator 360 determines an affinity score between the TV showand the “candy” topic based on the intersection between the first andsecond populations.

This process may be repeated for multiple TV shows, and the resultingset of affinity scores may be used to rank order TV shows by affinityscore. This provides HERSHEY'S with an indication of which TV shows haveaudiences that have greater affinity for the topic of “candy.”

VII. Example Use Cases for Affinity Scores

VII.A. Individual Affinity Scores

Affinity scores are useful individually. For example, a TV contentproducer may use the affinity score to determine whether the viewers ofone of their TV shows also watch another TV show. Similarly, they mayuse the affinity score to determine whether the viewers of one of theirTV shows are interested in a particular topic.

Affinity scores may also be determined between two different topics. Forexample, an advertiser may want to determine the extent of SM users whoare interested in both a particular brand (e.g., HERSHEY's brandchocolate) and a particular personal interest (e.g., movie watching).The affinity score then will represent the intersection in thepopulations of SM users who interested in both the topic of HERSHEY'sbrand chocolate and the topic of movie watching.

VII.B. Using an Affinity Score to Find Advertising Targets in SM

Populations of SM users, as defined by the Population Set Aggregator356, can be used as targets for advertisements delivered through thesocial networking system. Advertisers may desire to target suchpopulations because they reflect a relevant customer base for theirbrand. For example, PURINA may desire to target ads at the topic “petowners” as they are likely purchasers of pet food. Similarly, BMW maywant to target ads at fans of the TV show “TOP GEAR”, as they are likelyautomobile enthusiasts. However, such populations may not achieve thereach required by most SM advertising campaigns. Affinity scores providea mechanism for finding additional target populations attractive toadvertisers.

In one implementation, the affinity score may be used by an advertiserto find SM users who might be receptive to advertising by theadvertiser. For example, assume an advertiser desires to target SM userswho have high affinity to a particular show or topic (e.g. PURINA maydesire to target the topic “pet owners,” while BMW may want to targetthe show “TOP GEAR”). The affinity score provides a mechanism by whichan advertiser can find additional populations of SM users who may bereceptive to the advertiser's advertisements. Multiple affinity scorescan be computed between that show or topic and other TV shows in therepository. The advertiser can choose to target advertisements towardsSM users associated with those other TV shows that have a high affinityto the original show or topic (e.g., to those TV shows whose affinityscores are above a threshold). Here, the affinity score is used as ametric for estimating whether the two populations that make up theaffinity score are sufficiently similar such that advertising determinedto be effective with respect to one population is expected to beeffective to the other.

VII.C. Using Affinity Scores for Planning TV Ad Placements

Affinity scores are useful for identifying TV shows where brands shouldadvertise. Affinity scores can be used by brands to help define the TVmedia plans that dictate in what TV shows their ads will air. Also,affinity scores can be used by TV networks, to identify brands thatwould benefit from advertising in their shows. In either case, a numberof affinity scores may be calculated, where each affinity score isdetermined between a first topic and a varying second TV show. The firsttopic may be a brand topic associated w/the brand looking to advertise(e.g. PURINA), or it may be a lifestyle topic (e.g. pet owners)representing the interests of a segment of the population the brand ishoping to target. The first topic may also be replaced by a TV Show forwhich an advertiser wants to find similar shows in which to advertise.

Affinity scores may be determined between topic A and show B, topic Aand show C, topic A and show D, topic A and show E, etc. These affinityscores may be compared to determine the relative level of affinity thepopulations aligned with these different shows (e.g., shows B-E) havewith respect to topic A. These shows (again, shows B-E) may be rankedaccording to their affinity scores and may be used alone or inconjunction with other metrics, to determine in what TV shows a brandshould advertise. For example, the higher the affinity score, the morelikely the brand would benefit from advertising. The affinity scores mayalso be used in conjunction with other metrics to determine the price abrand should be willing to pay for such advertising. For example, thehigher the affinity score, the more the brand should be willing to pay.

VII.D. Using Affinity Scores for Measuring and Optimizing TV AdCampaigns

Affinity scores can be used to dynamically optimize TV ad campaigns. Foraffinity scores between a TV show and a topic related to a TV adcampaign, a number of different affinity scores may be generated whereeach affinity score varies with respect to TV show. For example, assumeHERSHEY'S runs an ad campaign in which a particular ad creative airsheavily on episodes of the show GLEE as well as on episodes of the showTHE VOICE. An affinity score may be determined between the TV show GLEEand HERSHEY'S ad creative. Another affinity score may be determinedbetween THE VOICE and HERSHEY'S ad creative. If the affinity score forthe ad creative with respect to GLEE is lower than with respect to THEVOICE, the ad creative can be dynamically replaced during thepresentation of GLEE with a different ad creative. Similarly, the adcreative can be added or featured more prominently during THE VOICE.This process for dynamically swapping out ad creatives may be managedmanually with human oversight, or may be managed programmatically basedon a set of rules with access to affinity data through an ApplicationProgramming Interface (APIs).

VII.E. Affinity Scores for TV Show Recommendations

The affinity score between each TV show and every other TV show may becompiled into a matrix where each cell represents the affinity between asource show (e.g., GLEE) and a target show (e.g., AMERICAN IDOL). Thismatrix can be used to automatically make recommendations to SM users fornew shows to watch, based on the other shows that the SM user hasauthored SM content items with respect to. The matrix can also be usedby TV networks or advertisers to determine in which shows to placepromotions for upcoming programming. For example, a TV network can usethe affinity matrix to choose which of their shows to advertise in oneof their other shows. This may be accomplished, for example, by rankingpotential placement targets (i.e., other TV shows) according to theaffinity between the show to be advertised and the other show in whichthe advertisement will appear. For example, the Fox network candetermine where to advertise GLEE by comparing the affinities providedby the matrix between GLEE and Fox's other shows. By placing ads forGLEE in other shows with which GLEE shares high affinity scores, thenetwork can target audiences that are more likely to have an affinityfor GLEE and thus optimize their advertising budget.

VII.F. Filtering Populations to Refine Affinity Scores

The affinity scores generated by the affinity server 130 may not provideexactly the output the user wanted. By filtering the population of SMusers matching a topic or event as described above, the affinity scoresthat are generated by the affinity server 130 may be refined to makethem more useful. For example, filtering of the populations may be usedto determine affinity scores with respect to individual episodes orseasons of a TV show (based on time of authorship of SM content items).

As another example, the population for the topic of “parents” may befiltered using gender criteria (e.g., SM authors who are women) tocreate a separate population of SM users who are classified as“mothers.” Affinity scores may be generated based on the intersectionbetween the population of “mothers” and various TV shows. These affinityscores may be used, for example by a baby food company, to determinewhich TV shows the baby food company should target their advertising in.

VII.G Using Affinity Scores in Conjunction with Real World AudienceMetrics

An affinity score between a first TV show and another TV show or topiccan be used in conjunction with an external metric of the real-worldaudience size for the first TV show to estimate the total number of realworld persons who have affinity for the other TV show or topic.

For example, an affinity score may be determined between a TV show and ademographic topic (e.g., SM users who are ages 24 to 30). This affinityscore estimates the number of SM users who are both interested in aparticular TV show and who are within the age range of 24 to 30. Thisaffinity score may be normalized so as to be represented as a proportionof the total number of SM users who are aligned with the TV show. Thisproportion may be combined with an external measure of the number ofpeople, in the real world, who have watched the TV show (i.e., are theviewing audience of the TV show) to determine the number of people inthe real world who are aged 24-30 who have watched the TV show. Thisexternal measure may be provided by an external source, such as NIELSEN.Estimating the size, in the real world, of a particular audiencedemographic, such as those viewers aged 24-30, is useful in makingairing and advertising decisions.

VIII. Displaying Time Based Media Audience Affinity

FIG. 6 illustrates one example screenshot of a user interface fordisplaying affinity scores between a TV show and multiple lifestyletopics of social media users, according to one embodiment. The userinterface is provided by affinity server 130 to a suitable client ordisplay device.

In the example of FIG. 6, the TV show is represented by the circle 702at the center of a circular shaped graphic 701. The size of the circle702 is based on the size of the population of SM users for that TV show.Each lifestyle topic is also represented by a circle 703. The size of acircle 703 for a lifestyle topic is based on the size of the populationof SM users for that lifestyle topic. A legend 709 provides anindication of how the sizes of circles 702 and 703 correspond to variouspopulation sizes. In one implementation, the size of the TV show circle702 is fixed regardless of the size of the population of SM users forthat TV show. Consequently, the legend 709 and sizes of circles 703 havesizes that are relative to the size of the population for the populationof viewers of the TV show. Generally, for both circles 702 and 703, thelarger the population, the bigger the circle.

The affinity score between the TV show and each lifestyle topic isrepresented by the distance 706 between the center of TV show circle 702and the center of lifestyle topic circle 703 (or, alternatively, basedon a point on the outer perimeter of either or both of these circles).The larger the affinity score between the TV show and the lifestyletopic, the smaller the distance 706. The circles 703 for the variouslifestyle topics for which affinity scores have been calculated aredisplayed so as radiate circularly around and outward from the TV showcircle 702.

A graphical overlay 710 provides an indication of the distances betweencircles 702 and 703 correspond to numerical affinity scores. In theexample of FIG. 6, the graphical overlay includes a series of concentricrings, where each ring is drawn a distance from the outer perimeter ofTV show circle 702 so as to represent a specific affinity score. In oneimplementation, the numerical values for affinity scores are displayedin normalized form, for example, “1.7×,” “1.2×”, “0.7×”, and “0.3×.” Inexample illustrated in FIG. 6, the affinity scores are normalized basedon the average affinity score between the TV show and a lifestyle topic.Thus, if a lifestyle topic had an affinity score of “1.7×” to the TVshow, then that lifestyle topic has an affinity score that is a multipleof 1.7 times the affinity score of the average lifestyle topic. In theexample illustrated in FIG. 6, all of the depicted lifestyle topics andtheir respective circles 703 have affinity scores above the average(i.e., all have normalized affinity scores greater than 1).

The number and density of the rings may vary between implementations.The distance between rings represents a difference between affinityscores. The distance between rings, and thus difference between affinityscores, may be linear, nonlinear, for example. Alternatively, a ring maybe displayed for each of a number of specifically ranked lifestyletopics. For example, a ring may be displayed at a distance correspondingto the affinity score of the lifestyle topic with the highest affinityscore, 5th highest affinity score, 10th affinity score, etc.

In addition to graphically illustrating the sizes of populations andaffinity scores, the population sizes and affinity scores may also benumerically represented. In the example of FIG. 6, the lifestyle topicsare displayed in a ranked list 707, where the lifestyle topics areranked according to their affinity scores 708 with respect to the TVshow. Similarly to the concentric rings of graphical overlay 710, theaffinity scores in ranked list 707 are normalized based on the averageaffinity score between the TV show and a lifestyle topic.

In one implementation, the graphic 701 does not display all of thelifestyle topics for which affinity scores have been calculated. Theranked list 707 allows the user to switch between pages 711 of lifestyletopics to view the affinity scores for those lifestyle topics that arenot currently displayed. Responsive to receiving a user input to changethe page 711, the ranked list 707 displays the lifestyle topics andtheir respective affinity scores on that page, according to their rank.The graphic 701 may also be updated to graphically depict the lifestyletopics from that page, along with their respective affinity scores,using circles 703 as described above. Thus, by switching between pagesthe display is updated to provide both a textual and visual depiction ofaffinity scores between lifestyle topics and the TV show.

Although illustrated with circular graphics and ranked lists, affinityscores and population sizes may be displayed in other formats as well,for example using pie charts, Venn diagrams, or other illustrativetools.

FIG. 7 illustrates one example screenshot of a user interface fordisplaying affinity scores between a TV show and a number of other TVshows, according to one embodiment. Affinity scores and population sizesare depicted graphically in the same manner as in FIG. 6 above. Theother TV shows for which affinity scores have been calculated are alsodisplayed in a ranked list, again ranked by their respective affinityscores as in FIG. 6.

The user interface also includes filters. In the example illustrated inFIG. 7, the filters are drop down menus 710, however in otherimplementations the user interface may display radio buttons, checkboxes, and/or text boxes to provide filtering options to the user. Thefilters provided to the user affect how the affinity server 130generates affinity scores. Specifically, the filters may include optionsfor affecting the SM filtering 502 process as described with respect toFIG. 5 above. The filters may also include options for affecting how thepopulation set aggregator 356 aggregates populations, as describedabove. Additionally, rather than affecting the generation of affinityscores, the filters provided the user may also affect which TV shows andtopic are graphically depicted.

A number of different filters 710 may be provided. A gender filteraffects whether affinity scores are calculated for male or female SMusers only, versus both together. A genre filter filters the display toonly include TV shows or topics matching a selected genre, where thegenre to choose from include, for example comedy, drama, sports, etc.712. A time of day filter filters the display to only include TV showsor topics aired during a certain time of day. Alternatively, the time ofday filter may affect the determination of affinity scores by onlyincluding in populations those SM users who have authored SM contentitems during the designated part of day. A network filter filters thedisplay to only include TV shows shown on a particular TV network (e.g.,ABC, NBC, CBS).

Once filtering criteria selections have been received from the user, asnecessary SM users populations are re-aggregated, affinity scores arere-determined, and the display is updated. Thus, the filters userinterface provides a convenient mechanism for the user to determine andrefine affinity scores.

The user interface also provides for the color coding 712 of the TVshows or topics. The color coding may be based on information pulledfrom the TV programming guide data 304, for example.

FIG. 8 illustrates one example screenshot of a user interface fordisplaying affinity scores between a TV show and a number of productbrand topics, according to one embodiment. Affinity scores andpopulation sizes are depicted graphically in the same manner as in FIG.6 above. The brands for which affinity scores have been calculated arealso displayed in a ranked list, again ranked by their respectiveaffinity scores as in FIG. 6.

IX. Additional Considerations

Although TV and advertising domains are described above, the methodsdescribed herein can be adapted to any domain using time based media(e.g., radio). The method of adaptation is general across differentdomains. Techniques and features used for event segmentation andannotation are adapted to reflect domain specific characteristics. Forexample, detecting events in football exploits the visibility of grassas it is represented in the color distributions in a video frame, whiledetecting events in news video or audio clip may exploit clues in theclosed captioning stream.

The foregoing description of the embodiments of the invention has beenpresented for the purpose of illustration; it is not intended to beexhaustive or to limit the invention to the precise forms disclosed.Persons skilled in the relevant art can appreciate that manymodifications and variations are possible in light of the abovedisclosure.

Some portions of this description describe the embodiments of theinvention in terms of algorithms and symbolic representations ofoperations on information. These algorithmic descriptions andrepresentations are commonly used by those skilled in the dataprocessing arts to convey the substance of their work effectively toothers skilled in the art. These operations, while describedfunctionally, computationally, or logically, are understood to beimplemented by computer programs or equivalent electrical circuits,microcode, or the like. Furthermore, it has also proven convenient attimes, to refer to these arrangements of operations as modules orengines, without loss of generality. The described operations and theirassociated modules or engines may be embodied in software, firmware,hardware, or any combinations thereof.

Any of the steps, operations, or processes described herein may beperformed or implemented with one or more hardware or software modulesor engines, alone or in combination with other devices. In oneembodiment, a software module or engine is implemented with a computerprogram product comprising a computer-readable medium containingcomputer program code, which can be executed by a computer processor forperforming any or all of the steps, operations, or processes described.

Embodiments of the invention may also relate to an apparatus forperforming the operations herein. This apparatus may be speciallyconstructed for the required purposes, and/or it may comprise ageneral-purpose computing device selectively activated or reconfiguredby a computer program stored in the computer. Such a computer programmay be persistently stored in a non-transitory, tangible computerreadable storage medium, or any type of media suitable for storingelectronic instructions, which may be coupled to a computer system bus.Furthermore, any computing systems referred to in the specification mayinclude a single processor or may be architectures employing multipleprocessor designs for increased computing capability.

Embodiments of the invention may also relate to a product that isproduced by a computing process described herein. Such a product maycomprise information resulting from a computing process, where theinformation is stored on a non-transitory, tangible computer readablestorage medium and may include any embodiment of a computer programproduct or other data combination described herein.

Finally, the language used in the specification has been principallyselected for readability and instructional purposes, and it may not havebeen selected to delineate or circumscribe the inventive subject matter.It is therefore intended that the scope of the invention be limited notby this detailed description, but rather by any claims that issue on anapplication based hereon. Accordingly, the disclosure of the embodimentsof the invention is intended to be illustrative, but not limiting, ofthe scope of the invention, which is set forth in the following claims.

What is claimed is:
 1. A computer-executed method, comprising:identifying a first population of social media users who are alignedwith a topic; identifying, by a computer processor, a second populationof social media users who are aligned with the time-based media event,and determining, by the computer processor and based on the firstpopulation and the second population, an affinity score associated withthe topic that is indicative of an affinity by social media users forboth the topic and the time-based media event; and generating fordisplay a visualization of the affinity score that includes a firstgraphical element representing the time-based media event, a secondgraphical element representing the topic, and a visual relationshipbetween the first graphical element and the second graphical element,the visual relationship dependent on the affinity score.